"NATURAL PRESERVATIVES" Anthony C. Dweck BSc CChem FRSC FLS FRSH SUMMARY This paper looks at the theoretical development of a natural preservative system using a data base on medicinal plants as a source of reference. The legal aspects of this concept are considered. The traditional methods of preservation, many taken from the food industry are summarised. The use of alcohol, glycerine, sugar, salt, dessication, anhydrous systems and temperature are amongst examples considered. KEY WORDS Natural preservation, traditional preservation, legal status. INTRODUCTION The subject of natural preservatives is one that probably has more academic interest than practical or economic virtue. However, it does have a wonderful marketing angle which may justify the higher raw material costs. The paper reviews the most commonly used methods of preservation that are already available to the formulator. The food and beverage industry may be called upon for many of these examples. LEGAL POSITION No preservative may be used which does not appear in Annex VI Part 1 or 2 of the EEC Cosmetic Directive 76/768/EEC - including 7th. amending Commission Directive 94/32/EC. However, there is no legislation for those natural materials, which, when used for their beneficial effect on the skin, may coincidentally have a positive effect on the total preservative requirement of the formulation. Of course, no material appearing in Annex II may be considered. The food industry often uses a preservation technique known as the “hurdle approach”, where there are a number of different methods that might eliminate organisms on their own if used at a high level, but which in a food might make the product unpalatable. The idea of using a whole variety of these “hurdles” to slowly weaken each organism, but at individual levels that would be ineffective is an almost alien concept to the cosmetic and toiletry industry. SUGAR High levels of sugar can preserve against spoilage organisms, this may be seen in jams, preserves, certain sweet pickles and marmalades. This is also an important factor in the preservation of boiled sweets and chocolates etc. Increasingly, it will be noticed that many products now have to be kept in the refrigerator of freezer once opened, because sugar has been replaced by artificial sweetener which is cheaper and healthier to eat, but which compromises the self-preservation of the product. HONEY Honey in its undiluted form is also a natural preservative and, indeed, there are many learnéd papers citing honey as a viscous barrier to bacteria and infection. ALCOHOL Not all organisms are bad! The production of alcohol from sugar by yeast is an industry in its own right. A wine carefully produced using sterilised equipment and fermented to 13% by volume will just about resist further infection from external organisms, once the ferment has completed. It is during the time of the fermentation process that the fermenting must is vulnerable to infection. The naturally produced fermentation grade alcohol can be concentrated by distillation and used as a natural preservative in toners, aftershaves and colognes. HEAT Heating, cooking and pasteurisation is another natural form of preservation that will sterilise products, especially where that product is designed as a one-shot use product - for example, a phial or a sachet. Alternatively, once opened, the product can be stored in the fridge of freezer to prevent microbiological degradation. DESICCATION Removing water from a product or making it totally dehydrated will greatly reduce the possibility of spoilage, however, it must be recognised that the presence of spore-bearing organisms could become active once that water is reintroduced. ANHYDROUS In a similar vein, one could make products with materials that do not contain any traces of water, i.e. to deliberately design and formulate a totally anhydrous product. However, creams that can be finished by the consumer, by introducing water to the blend of oils, fats and waxes are prone to the same restrictions as the dessicated products. SALT The use of extreme levels of salt as used by the ancient mariners to preserve their meat is effective and it very likely that the preservation of the Egyptian mummies was, in part, achieved by the 40 day treatment in natron (a concentrated brine solution that osmotically drained the tissues of water). COLD Placing a product in the cold merely 'stops the clock' on microbiological growth and this is perfectly fine, provided the product was sterile when it was placed in the cold and/or had sufficient preservative 'mass' to counter any new organisms subsequently introduced. ACID pH The preservative activity can be boosted by operating at as low a pH as possible. Natural acidity could be obtained from one of the many of the alpha hydroxy acids (AHAs) which are obtained from citrus species, where the major components are citric and malic acids. CHELATING AGENTS In addition to formulating at low pH, chelating agents such as ferulic acid extracted from rice bran, could be added to enhance the activity of the natural preservative. ANTIOXIDANTS Antioxidants such as natural tocopherol and ascorbic acid will further aid in preservation, as well as reducing the potential rancidity. GLYCERINE High levels of vegetable glycerine, up to 15-20%, will also have a preservative effect, similar to that effect obtained by the use of high levels of sugar. PLANTS SELF-PRESERVATION Plants in the wild do not go mouldy, and yet they are in an environment that predisposes them to suffer from the infestation of all manner of spoilage organisms. Yeasts, moulds and bacteria abound in the soil, all working to breakdown dead plant material and provide fresh humus for those plants living in the soil. Living plants resist the natural forces of disintegration. The chemicals present in all parts of the plant protect it from the environment. However, examples can be seen where tampering with the plant leads to a reduction in the efficacy of this natural mechanism. It is concluded, that the chemical constituents within each plant clearly differ in composition. Furthermore, that there may be in certain species a chemical or group of chemicals present in the plant that is capable of killing micro-organisms. This chemical composition varies according to whether the plant is alive or dead, and in certain/most plants will vary according to season. In many cases, when these plants are extracted, it is found that the extracts are capable not only of resisting certain spoilage organisms, but in some cases can actively act to destroy them. The time and speed of extraction of the fresh plant is often critical if the preservative activity is to be retained. COMMERCIAL PRODUCTS There are a number of natural preservatives available on the market that is not strictly speaking legal, since they have no entry in Annex VI as a permitted preservative. However, the use of a plant for its marketing claim, or for other functional benefits smudges the issue. One may use a number of plant derivatives as fragrance components and coincidentally achieve a lower overall preservative requirement for the product in which they are used. There are many cases where plants may contain paraben-type compounds in addition to other functional actives and the difficulty is to decide whether the botanical is being used as a preservative or for other legitimate and perfectly legal benefits. Plants used to eliminate Candida albicans – a review of the literature A survey of papers published between 1995 and 1999 showed a tremendous activity in the examination of botamicals for their antimicrobial and antiseptic effects. A cross- section of plants examined is shown below. Abies (fir) species The antimicrobial activity of essential oils isolated from nine Abies species (A. koreana, A. alba, A. pinsapo, A. concolor, A. firma; A. nordmanniana subsp. nordmanniana which are plantation forms; and A. cilicica subsp. cilicica, A. cilicica subsp. isaurica and A. nordmanniana subsp. bornmuelleriana which are natural forms) against bacteria (Escherichia coli, Bacillus megaterium, B. cereus, B. subtilis, B. brevis, Pseudomonas aeruginosa, Listeria monocytogenes, Klebsiella pneumoniae, Enterobacter aerogenes, Staphylococcus aureus) and yeasts (Saccharomyces cerevisiae and Candida albicans) were investigated using a disc diffusion method. The essential oils could be classified into 3 groups according to the strength of their antimicrobial activities. The first group of essential oils of A. pinsapo and A. concolor had no antimicrobial activity, the second group of essential oils, isolated from A. alba and A. firma, had a modest activity. The third group, A. koreana, A. cilicica subsp. cilicica, A. cilicica subsp. isaurica, A. nordmanniana subsp. nordmanniana and A. nordmanniana subsp. bornmuelleriana, had the highest antimicrobial activity against the bacteria and yeast species tested. Surprisingly, it was found that most of the essential oils used in this study had little effect on the growth of E. coli. The essential oils of the Abies species tested were more active against yeast species than against bacteria, and the antimicrobial activity of essential oils was variable, depending on the bacterial strains and the source of the essential oil. [Bagci, et al] Aframomum melegueta 6-Paradol and 6-shogaol were isolated from the seeds of Aframomum melegueta following bioactivity-guided fractionation. These compounds were active against Mycobacterium chelonei [M. chelonae], M. intracellulare, M. smegmatis and M. xenopi (MIC values of 10-15 ug/ml). The antimicrobial properties of derivatives were also investigated. The desmethyl derivative of 6-paradol retained antimycobacterial activity, and was more active against Candida albicans than either 6-paradol or 6-shogaol.[Galal] Alectoria sarmentosa - Lichen Four antimicrobial compounds, identified as (-)-usnic acid, physodic acid, 8'-O-ethyl- beta-alectoronic acid and a new dibenzofuranoid lactol named alectosarmentin, were isolated from the ethanol extract of A. sarmentosa. Alectosarmentin exhibited activity against Staphylococcus aureus and Mycobacterium smegmatis at 25 ug/ml; the known compounds exhibited activity against these 2 bacteria and against Candida albicans.
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